2013 Laboratory E: Inverse Problems

Sunday, January 13, 2019 8:02:50 PM

Select the Inverse Solver Panel.
For Fwd Solver Engine: select "Scaled Monte Carlo - NURBS (g=0.8, n=1.4)", for Inv Solver Engine: select "Standard Diffusion (Analytic - Isotropic Point Source)".
In Solution Domain: select "Steady State( $R (ρ)$ )".
Set begin and end locations to 0.5 and 9.5 mm, respectively with 10 points (every 1 mm).
Set Optimization Parameters to: $μ a$ and $μ' s$ .
Simulate measured data: set "Forward Simulation Optical Properties:" to: $μ a$ = 0.01 mm^-1, $μ' s$ = 1 mm^-1, g = 0.8 and n = 1.4 and 2% noise.
Confirm the Hold On checkbox is checked.
Click the Plot Measured Data button.
Set Initial Guess Optical Properties: to: $μ a$ = 0.05 mm^-1, $μ' s$ = 1.5 mm^-1, g = 0.8 and n = 1.4.
Click the Plot Initial Guess button.
Click the Run Inverse Solver button.

To what optical property values did the inverse solver converge? (Scroll to the bottom of the page to see the output).
Why are the converged values not exactly the forward simulation optical properties?
Perform the same analysis with 0% noise added to the simulated measured data. How accurate are the converged properties now?
Perform the same analysis with initial guess $μ a$ = 0.001 mm^-1, $μ' s$ = 0.5 mm^-1, g = 0.8 and n=1.4. How accurate are the converged properties now?

Perform the same analysis changing the Inv Solver Engine to "Scaled Monte Carlo - NURBS(g=0.8, n=1.4)".
Which Model Engine provided the more accurate converged values?

Repeat II using only 2 detectors. Can you strategically place the two detectors to obtain the same accuracy in the converged values as you obtained with 10 detectors?
Use the plots generated in Lab C, Section VII that showed the sensitivity of spatially-resolved diffuse reflectance to optical properties to help guide their placement.

Go to the Forward Solver/Analysis Panel
For Fwd Solver Engine: select "Scaled Monte Carlo - NURBS (g=0.8, n=1.4)"
In Solution Domain: select "Steady State( $R (f x)$ )".
Set start and stop locations to 0 and 0.5 /mm, respectively with 51 points (every 0.01/mm).
In Optical Properties: enter $μ a = 0.01$ mm^-1, $μ' s$ =1mm^-1, n=1.4.
Click the Plot Reflectance button.
Confirm the Hold On checkbox is checked.
Now plot the spatial frequency domain reflectance when the tissue absorption is 10% higher i.e., for Optical Properties: of $μ a =$ 0.011mm^-1, $μ' s$ =1mm^-1
Click the Plot Reflectance button.
Now, in the Plot View window, click the Curve Radio Button in the Normalization Controls. This operation divides all spatial frequency domain reflectance results in the plot view window by the first $R (f x)$ result. Thus each result becomes $R i (f x) / R 1 (f x)$ where $R 1 (f x)$ is the first reflectance result and $R i (f x)$ is any successive reflectance result. This results in the first $R 1 (f x)$ result getting transformed to a series of '1' values.
Note what spatial frequency regime shows the most sensitivity to $μ a$ changes?

Click Clear All and set Normalization to None.
In Optical Properties: enter $μ a = 0.01$ mm^-1, $μ' s$ =1mm^-1, n=1.4.
Click the Plot Reflectance button.
Confirm the Hold On checkbox is checked.
Now plot the spatial frequency domain reflectance when the tissue scattering is 10% higher i.e., for Optical Properties: of $μ a =$ 0.01mm^-1, $μ' s$ =1.1mm^-1
Now, in the Plot View window, click the Curve Radio Button in the Normalization Controls. This operation divides all spatial frequency domain reflectance results in the plot view window by the first $R (f x)$ result. Thus each result becomes $R i (f x) / R 1 (f x)$ where $R 1 (f x)$ is the first reflectance result and $R i (f x)$ is any successive reflectance result. This results in the first $R 1 (f x)$ result getting transformed to a series of '1' values.
Note what spatial frequency regime shows the most sensitivity to $μ' s$ .

Click Clear All and set Normalization to None.
Select the Inverse Solver Panel.
For Fwd Solver Engine: select "Scaled Monte Carlo - NURBS (g=0.8, n=1.4)", for Inv Solver Engine: select "Standard Diffusion (Analytic - Isotropic Point Source)".
In Solution Domain: select "Steady State( $R (f x)$ )".
Set begin and end locations to 0 and 0.5 /mm, respectively with 11 points (every 0.05/mm).
Set Optimization Parameters to: $μ a$ and $μ' s$ .
Simulate measured data: set "Forward Simulation Optical Properties:" to: $μ a$ = 0.01 mm^-1, $μ' s$ = 1 mm^-1, g = 0.8 and n = 1.4 and 2% noise.
Confirm the Hold On checkbox is checked.
Click the Plot Measured Data button.
Set "Initial Guess Optical Properties:" to: $μ a$ = 0.05 mm^-1, $μ' s$ = 1.5 mm^-1, g = 0.8 and n = 1.4.
Click the Plot Initial Guess button.
Click the Run Inverse Solver button.

To what optical property values did the inverse solver converge? (Scroll to the bottom of the page to see the output).
Perform the same analysis with 0% noise added to the simulated measured data. How accurate are the converged properties now?
Perform the same analysis with initial guess $μ a$ = 0.001 mm^-1, $μ' s$ = 0.5 mm^-1, g = 0.8 and n=1.4. How accurate are the converged properties now?

Go to the Inverse Solver Panel.
Follow the instructions provided in Section V except modify the Spatial Frequency begin and end values to those obtained in Section IV. "Impact of Optical Properties on Spatial Frequency Domain Reflectance".
Rerun the inverse solver.

Were you able to improve the $μ a$ and $μ' s$ converged properties?
In what spatial frequency domain is reflectance most sensitive to $μ a$ ? Why is this?
In what spatial frequency domain is reflectance most sensitive to $μ' s$ ? Why is this?